DE3544933A1 - Evaporative cooling for an industrial furnace with a quantity of heat which varies over time - Google Patents

Abstract

The invention relates to an evaporative cooling for an industrial furnace with a quantity of heat which varies over time, composed of at least one cooling element and a steam drum which is connected to the feed line of the cooling element and to the discharge line thereof and to a feed-water line. As a result of the quantity of heat, varying over time, of specific industrial furnaces, evaporative cooling also leads to steam generation which varies sharply over time and, resulting therefrom, a sharply varying volume displacement in the steam/water mixture lines between the cooling elements and the steam drum, which, in turn, leads to a sharply varying water level in the steam drum. In order to avoid this disadvantage in a simple manner, the invention proposes that the feed-water line (6) open into the discharge line (4) of the cooling element, in the region preferably directly behind the latter. By leading the feed water into the start of the steam/water mixture line, as directly beside the cooling element as possible, it is achieved that behind the cooling element, in each case in dependence on thermal loading, the steam generated in the cooling element is condensed back again, wholly or partially, since the feed water in almost all cooling systems is colder than the circulation water. This leads to a homogenisation of the circulation quantity and to the drum having a water level which varies to a much lesser degree (figure). <IMAGE>

Description

The invention relates to evaporative cooling for Industrial furnace with fluctuating heat, such as e.g. an arc furnace, a converter, a pan furnace or the like, consisting of at least one cooling element, such as. a wall element, a cover element, one Hood, an exhaust pipe, a waste heat boiler or the like, and a steam drum, which is connected to the inlet pipe of the Cooling element and with its drain line and with a Feed water pipe is connected.

Due to the fluctuating heat accumulation of certain ten industrial ovens also results in a strong time fluctuating vapor generation of evaporative cooling and this results in a strongly fluctuating volume displacement in the steam-water mixture pipes between the cooling elements and the steam drum, which in turn becomes a strongly fluctuating water level in the steam drum.

This disadvantage can be increased fix the steam drum, however, this represents a comparative  wise elaborate solution.

To avoid this disadvantage in a simple manner proposed according to the invention that the feed water line preferably in the drain line of the cooling element in the area se flows directly behind this. By the introduction tion of the feed water in the beginning of the steam-water ge mixing line is as close as possible to the cooling element achieved that behind the cooling element depending on the heat load all or part of the steam generated in the cooling element which is recondensed because the feed water in almost all Cooling systems are colder than the circulating water. As a result this leads to a more even circulation and a much less fluctuating water level in the drum, and that by a lower volume displacement in the Drain pipe. So it is also possible to use the installed Reduce pump performance as the expected maximum Pressure loss in the system becomes smaller.

The feed water pipe extends with its mouth to about the middle of the cross-section of the drain pipe, so that a central introduction of the feed water takes place. The feed water line advantageously bends in the axis of the Drain line on, the axis of the drain line ent neither against or in the flow direction of the steam water  Mixture directed in the drain line of a cooling element can be. It is also possible to use the feed water line to let a T-piece flow into the drain pipe. In in any case, there is good mixing with the steam-what This mixture takes place in the drain line.

In order to increase the distribution effect even further, the feed water pipe at its end in the drain pipe with a distributor be equipped.

The feed water pipe is the wall of the Ab area passing through the transmission line from an overtube to protect them against excessive thermal stress.

According to a further proposal of the invention Feed water supply depending on the heat load regulated on one or more cooling elements. To the rain Development of the feed water supply is advantageously a plus Component controller use, the regulation in Dep the steam extraction quantity and / or the water level in the steam drum and / or the quantity of feed water and / or the proportion of steam in one or more drain lines follows.

The invention also extends to evaporation  cooling for an industrial furnace with fluctuating time Heat accumulation, consisting of several in parallel and / or in series mutually arranged cooling elements and a steam drum, the with the supply lines of the cooling elements and with their Drain pipes and with a feed water pipe in ver bond stands. With such an evaporative cooling with The feed water line opens into several cooling elements the drain lines of the individual cooling elements and / or Groups of the same.

An embodiment of the invention is based on the drawing voltage explained in more detail, which is a schematic representation shows evaporative cooling.

1 is an industrial furnace with several cooling elements, for example an electric arc furnace for steel production, whose individual cooling elements can be arranged one behind the other and / or parallel to one another, but this is not shown for reasons of better clarity, quite apart from the fact that these Design is known per se.

The steam drum 2 is connected to the cooling elements of the industrial furnace 1 via the inlet line 3 and the outlet line 4 . With 5 the line for steam extraction is marked. The feed water is introduced via the feed water line 6 into the drain line 4 of the cooling elements of the industrial furnace 1 , preferably in its beginning, ie in the area immediately behind the cooling elements of the industrial furnace 1 . This ensures that each recondensed behind the cooling elements of the industrial furnace 1 according to the thermal load of the steam generated in the cooling elements wholly or partly, is achieved, resulting in a homogenization of the circulation rate and a substantially constant the attitude of the water level in the steam drum. 2

The feed water is supplied via the feed water line 6 as a function of the heat load on one or more cooling elements. There is a multi-component controller 9 , which is connected via lines 10 with actual Wertge bern 11 for detecting the steam extraction amount in the Lei device 5 , the water level of the steam drum 2 , the Dampfan part in the drain line 4 and the feed water quantity in the feed water line 6 . The output of the multi-component controller 9 is connected via line 7 to the control valve 8 in the feed water line 6 , via which the feed water supply is regulated.

Claims (11)

1. Evaporative cooling for an industrial furnace with fluctuating heat, consisting of at least one cooling element and a steam drum, which is in connection with the supply line of the cooling element and with its drain line and with a feed water line, characterized in that the feed water line ( 6 ) in the drain line ( 4 ) of the cooling element in the area preferably opens directly behind this. 2. Evaporative cooling according to claim 1, characterized in that the feed water line ( 6 ) extends with its mouth to about the middle of the cross section of the drain line ( 4 ) of a cooling element. 3. evaporative cooling according to claim 1 or 2, characterized in that the feed water line (6) bends in the axis of the discharge line (6). 4. Evaporative cooling according to claim 1 or one of the preceding, characterized in that the outlet opening from the kink in the feed water line ( 6 ) is directed against the flow direction of the steam-water mixture in the outlet line ( 4 ) of a cooling element. 5. Evaporative cooling according to claim 1 or one of the preceding, characterized in that the outlet opening from the kink of the feed water line ( 6 ) is directed in the flow direction of the steam-water mixture in the outlet line ( 4 ) of a cooling element. 6. Evaporative cooling according to claim 1 or one of the preceding, characterized in that the feed water line ( 6 ) opens into the drain line ( 4 ) via a T-piece. 7. Evaporative cooling according to claim 1 or one of the preceding, characterized in that the feed water line ( 6 ) is equipped at its end in the drain line ( 4 ) with a distributor head. 8. Evaporative cooling according to claim 1 or one of the preceding, characterized in that the feed water line ( 6 ) in its area passing through the wall of the drain line ( 4 ) is surrounded by an over tube. 9. Evaporative cooling according to claim 1 or one of the previous, characterized in that the food water supply depending on the heat load one or more cooling elements is regulated. 10. Evaporative cooling according to claim 1 or one of the preceding, characterized in that a multi-component controller is used for regulating the feed water supply and the control is dependent on the amount of steam withdrawn and / or the water level in the steam drum and / or the amount of feed water and / or the Steam portion takes place in one or more drain lines ( 4 ). 11. Evaporative cooling for an industrial furnace with fluctuating heat, consisting of a plurality of cooling elements arranged in parallel and / or in series with one another and a steam drum which is connected to the supply lines of the cooling elements and to their drain lines and to a feed water line, characterized in that that the feed water line ( 6 ) opens into the drain lines ( 4 ) of the individual cooling elements and / or groups thereof.